Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B60—VEHICLES IN GENERAL
  • B60R—VEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
  • B60R19/00—Wheel guards; Radiator guards, e.g. grilles; Obstruction removers; Fittings damping bouncing force in collisions
  • B60R19/02—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects
  • B60R19/24—Arrangements for mounting bumpers on vehicles
  • B60R19/26—Arrangements for mounting bumpers on vehicles comprising yieldable mounting means
  • B60R19/34—Arrangements for mounting bumpers on vehicles comprising yieldable mounting means destroyed upon impact, e.g. one-shot type
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B60—VEHICLES IN GENERAL
  • B60R—VEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
  • B60R19/00—Wheel guards; Radiator guards, e.g. grilles; Obstruction removers; Fittings damping bouncing force in collisions
  • B60R19/02—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects
  • B60R19/18—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects characterised by the cross-section; Means within the bumper to absorb impact
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B60—VEHICLES IN GENERAL
  • B60R—VEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
  • B60R19/00—Wheel guards; Radiator guards, e.g. grilles; Obstruction removers; Fittings damping bouncing force in collisions
  • B60R19/02—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects
  • B60R19/18—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects characterised by the cross-section; Means within the bumper to absorb impact
  • B60R2019/186—Additional energy absorbing means supported on bumber beams, e.g. cellular structures or material
  • B60R2019/1866—Cellular structures

Definitions

• the present invention relates to the field of bumper assemblies for motor vehicles.
• a motor vehicle is commonly equipped with bumper assemblies arranged at the front and / or rear of the vehicle to protect the vehicle in a collision. These bumper assemblies are configured to absorb the kinetic energy released during such collisions and thus limit the damage they can cause, both for the vehicle users and for the vehicle itself.
• the bumper assemblies are made at least partly of steel. If these bumper assemblies are inexpensive, they have the disadvantage of being very heavy, which in particular has the effect of increasing the fuel consumption of the vehicle.
• the present invention is in this context and proposes a bumper assembly broken down into three main parts secured together, which improves the profitability of the production lines of these bumper assemblies and reduce the number of junction zones at which these bumper assemblies are weakened.
• the object of the present invention thus relates to a bumper assembly for a motor vehicle, comprising a cross member and a shock absorber, and at least one rib which extends from the shock absorber, characterized in that the cross member and the shock absorber are made in one piece.
• the term "made in one piece” means that the cross member and the shock absorber form a single piece and thus form a continuity of material so that it is impossible to separate the cross member of the shock absorber without generating breaks at one of these elements.
• the cross member, the shock absorber and the said at least one rib are made in one piece.
• the term "made in one piece” means that the cross member, the shock absorber and the at least one rib form a single piece and thus form a continuity of material so that it is impossible to separate these elements without generating breaks at one of these elements.
• the bumper assembly further comprises a second shock absorber, the bumper assembly comprising a first half-shell and a second half-shell configured to generate a hollow body, each half -coque respectively having an inner face facing the other half-shell and delimited by edges, these two half-shells being secured to one another in a peripheral connecting surface, at the edges of their inner faces to form the two shock absorbers and at least a portion of the cross member.
• the first half-shell comprises at least one rib extending from the inner face of this first half-shell
• the second half-shell comprises at least one rib extending from the inner face of this second half-shell
• the two half-shells are arranged so that the at least one rib of the first half-shell is arranged facing the at least one rib of the second half-shell and in that the first half-shell and the second half-shell are secured at the ribs.
• the bumper assembly comprises a first half-shell and a second half-shell respectively having an inner face facing the other half-shell and delimited by edges, these two half-shells being secured to each other in a peripheral connecting surface, at the edges of their inner faces, to form the two shock absorbers and at least a portion of the crossbar.
• the first half-shell comprises at least one rib extending from one edge to the other of the inner face of this first half-shell
• the second half-shell comprises at least one rib extending a edge to the other of the inner face of this second half-shell
• the two half-shells being arranged so that the at least one rib of the first half-shell is arranged opposite the at least one rib of the second half-shell half-shell, the first half-shell and the second half-shell being secured in an internal connecting surface at the ribs.
• An internal connecting surface thus forms part of a junction plane between the first half-shell and the second half-shell, this joining plane being defined by a plurality of ridges of the ribs formed on the inner faces of each half-shell. shell.
• the first half-shell can be likened to a lower half-shell and the second half-shell can be assimilated to an upper half-shell, this lower half-shell and the upper half-shell being symmetrical with respect to their junction plan.
• These two half-shells can thus advantageously be manufactured by means of a single mold, which makes it possible to reduce the costs and manufacturing times of these parts.
• the half-shells according to the invention can be of different shape, it is sufficient that the two half-shells are configured to generate a hollow body.
• the half-shells may each have a concave section profile, the inner face being the face within the hollow so that when the two half-shells are facing each other, a space hollow is thus generated between the two half-shells by their section profile.
• each half-shell comprises a panel which consists of three flat portions, a central flat portion located between the two other flat end portions each being located at a transverse end of the half-shell.
• the central flat portion is connected to each end flat portion by an inclined section, otherwise called ramp, so that the central flat portion is offset vertically relative to the two end plane portions.
• the half-shell, and in particular the panel have an omega profile section.
• the extremal planar portions are arranged in the same plane while the central flat portion is arranged in a distinct plane and parallel to the plane of the extreme flat portions.
• each half-shell comprises a central part, this central part comprising at least one rib whose first edge participates in forming the internal connecting surface and a second edge of which is part of a plane delimiting a front face of the half-shell concerned.
• the first edge of the rib corresponds to an edge of this rib extending between two edges delimiting the inner face of the half-shell in question and the second edge of the rib corresponds to an edge of this rib which extends from a edge of the inner face to an outer face, that is to say a face opposite to the inner face of the half-shell concerned.
• the outer face of the half-shell is a lower face of the latter.
• central portion of each half-shell is meant a portion of the half-shell extending between two shock half-shock absorbers. These half-shock absorbers are thus arranged at each of the transverse ends of the half-shells and are intended to form the two shock absorbers of the bumper assembly according to the invention, once the half-shells joined.
• each half-shell comprises in one piece the central portion and side portions which project from this central portion, perpendicular to a main direction of elongation thereof.
• the term "in one piece” means that each half-shell forms a single assembly, can not be separated without causing damage to the central portion or one or the other of the side portions.
• each half-shell comprises a half-cross and two half shock absorbers, respectively intended to be secured to the half-cross and each of the half-shock absorbers of the other half-shell.
• the crossbar of the bumper assembly has a main direction of elongation parallel to each of the main elongation directions of the central portions of the two half-shells and that the shock absorbers of this bumper assembly s extend mainly in a direction perpendicular to this direction of main elongation of the cross.
• the front faces of the half-shells are intended to be disposed towards an environment outside the vehicle on which the bumper assembly is intended to be integrated.
• the front face of each half-hull is turned towards a front environment of the vehicle.
• each half-shell comprises an array of ribs extending from its respective inner face, at least a first rib of each of these rib networks forming the internal connecting surface with at least one second rib of the other network of ribs, the at least one first rib and the at least one second rib being arranged opposite one another.
• the internal connecting surface is part of a joining plane between the rib network of the first half-shell and the rib network of the second half-shell, this joining plane being a horizontal plane.
• the internal connecting surface is formed by all the ribs of the rib network of the first half-shell and by all the ribs of the rib network of the second half-shell. , the ribs of these networks being secured in pairs.
• the rib network of the first half-shell is identical to the network of ribs of the second half-shell, each rib of the rib network of the first half-shell being arranged opposite a rib of the network of ribs of the second half-shell.
• the network of ribs of each half-shell is a matrix network.
• a reinforcing piece is secured on both front faces of the half-shells joined together.
• the first half-shell is secured to the second half-shell, thereby creating a first portion of the cross member of the bumper assembly according to the present invention, and that the reinforcing piece is secured to this first part of the cross.
• the crossbar of the bumper assembly according to the present invention is thus formed by the junction of the two half-shells and this reinforcing piece.
• a peripheral edge of the reinforcing piece is secured to a periphery delimiting the front faces of the two half-shells assembled together.
• the peripheral edge of the reinforcing piece is secured to a periphery delimiting a front face of the first portion of the cross member formed by the joining of the half-shells together.
• the reinforcement part comprises a front surface intended to be turned towards the external environment of the vehicle and a rear surface, opposite to this front surface, intended to be secured to the front faces of the two half-shells joined together, it is that is to say that this rear surface is intended to be secured to the front face of the first part of the crossbar.
• the rear surface of the reinforcing piece may comprise at least one rib, this at least one rib being secured to the front faces of the two half-shells assembled together.
• this at least one rib formed on the reinforcement piece is then arranged at least opposite one of the ribs formed on the front faces of the half-shells in order to facilitate the fastening of this reinforcing piece on said half-shells.
• the reinforcement piece is configured to generate a hollow body when it is assembled on the two half-shells. More specifically, this reinforcement piece is configured so that the crosspiece that it participates in forming with the two half-shells has a hollow body defined by a space between this reinforcing piece and these two half-shells, once assembled together. .
• This hollow body notably allows better shock absorption by facilitating the deformation of the cross member in the event of a collision.
• This hollow body extends over at least a central portion of the cross member.
• the hollow body generated by the assembly of the reinforcing piece on the two half-shells can extend over an entire dimension of the cross member, along the main direction of elongation of this crossbar, that is to say from one transverse end to the other transverse end of this cross.
• the hollow body can extend from one shock absorber to the other.
• the two half-shells comprise a composite material such as PolyAmide 6 with glass or carbon fibers (PA6 GF30).
• the materials used are thermoplastic composites reinforced with glass fibers.
• the matrix of these composite materials can be selected from resins commonly used in the automobile (eg polypropylene).
• the reinforcement may occasionally be selected from other types fibers such as carbon, kevlar, vegetable / natural fibers.
• the combination of thermoplastic resin and fiberglass has the advantage of offering a good compromise between mechanical characteristics and cost.
• the connections between the two half-shells and the reinforcing beam may be made by welding or gluing.
• the reinforcing piece is thus made of a material for welding or gluing of this reinforcing piece on the half-shells.
• This reinforcing piece may for example comprise a composite material.
• this reinforcing piece can be made of the same material as the half-shells.
• each half-shell comprises fastening means arranged at the free ends of each of the shock absorbers.
• the invention also relates to an automobile vehicle comprising a bumper assembly according to the present invention, the shock absorbers of this bumper assembly being interposed between the cross member of the bumper assembly and a spar of the motor vehicle.
• FIG 1 is a perspective view of a bumper assembly according to the present invention comprising two half-shells and a reinforcing piece;
• FIG. 2 is an exploded view of each of the parts participating in the bumper assembly according to the present invention.
• FIG. 3 is a perspective view of the bumper assembly illustrated in FIG. 1 in which the reinforcing piece has been removed;
• FIG 4 is a schematic representation of a section made in a transverse plane of the two half-shells assembled together.
• the names longitudinal, transverse, vertical, horizontal, left, right, upper, lower, front and rear refer to the orientation, in a trihedron L, V, T, of a bumper assembly 1 illustrated.
• the axis L represents the longitudinal direction
• the axis T represents the transverse direction
• the axis V represents the vertical direction of the considered object.
• a bumper assembly 1 of the present invention extends mainly along a transverse axis T.
• the left and right denominations are evaluated with respect to a position along this transverse axis T, on both sides.
• Another of a longitudinal axis L Another of a longitudinal axis L.
• a vertical axis V symbolizes a vertical direction, which is perpendicular to the longitudinal axis and to the transverse axis described above.
• the upper or lower denominations refer to orientations along the vertical axis V.
• the front or back denominations refer to orientations along the longitudinal axis L.
• FIG. 1 is a perspective view of the bumper assembly 1 according to the present invention comprising a cross member 2 and two shock absorbers 3 ⁇ According to the present invention, this bumper assembly 1 is made, at least partly in a composite material.
• the cross member 2 has a main direction of elongation merged with the transverse axis T and comprises a central portion 5 and two transverse ends 4 located on either side of this central portion 5, the along the transverse axis T.
• the shock absorbers 3 are arranged at each of these transverse ends 4 ⁇ They extend projecting from the cross member 2, from the transverse ends 4 of the cross member 2 and towards the rear of the vehicle.
• the shock absorbers 3 here respectively have a substantially trapezoidal shape and they are symmetrical with respect to a median vertical and longitudinal plane, that is to say a plane passing through a center of the vehicle on which the protective assembly is mounted. shock 1 and in which are inscribed the L and V axes of the trihedron as shown in Figure 1.
• Each of these shock absorbers 3 comprises fastening means 6 configured to allow the attachment of the bumper assembly 1 to a motor vehicle.
• the bumper assembly 1 is intended to be integrated on a front face of the motor vehicle, the shock absorbers 3 then being interposed between a spar of said motor vehicle and the cross member 2.
• the fastening means 6 made on the Shock absorbers 3 thus make it possible to fix the bumper assembly 1 on the spar of the motor vehicle.
• these fixing means 6 may for example be fastening plates which extend mainly in a transverse and vertical plane and which are arranged at a rear longitudinal end of each of the dampers. of shocks 3 ⁇
• the shock absorbers 3 of the bumper assembly 1 are configured to absorb the energy released during an impact between the motor vehicle on which the bumper assembly is integrated and an object outside this motor vehicle. These shock absorbers 3 thus allow, by their deformation, to limit damage to the motor vehicle and its occupants during such shocks. Advantageously, these shock absorbers 3 allow to leave intact the vehicle structure in case of collision at low speed. "Low speed” means a speed at least less than 15km / h.
• FIG. 2 is an exploded view of the bumper assembly 1 according to the present invention. As can be seen, this bumper assembly 1 comprises two half-shells 7, 8 and a reinforcement piece 9
• the bumper assembly 1 thus comprises a first half-shell 7, called “upper half-shell 7” and a second half-shell 8, called “lower half-shell 8".
• these two half-shells 7, 8 are symmetrical to each other with respect to a horizontal plane, that is to say a longitudinal and transverse plane as reference to the trihedron worn on the figures.
• Each half-shell 7, 8 comprises a front face 10, this front face 10 comprising a central portion 11 and two transverse ends 12.
• Each half-shell 7, 8 also comprises two lateral portions 13 respectively disposed at one of the transverse ends 12 of its front face 10.
• the central portions 11 of each half-shell 7, 8 extend mainly in a direction of principal elongation parallel to the transverse axis T and the lateral portions 13 of each of these half-shells 7 , 8 respectively extend in directions perpendicular to this main elongation direction of each half-shell.
• each lateral portion 13 extends parallel to the longitudinal axis L.
• each half-shell comprises, in one piece, a half-cross and two half shock absorbers.
• Each half-shell 7, 8 further comprises an inner face 14 and an outer face 15, the inner face 14 of the upper half-shell 7 being turned towards the inner face 14 of the lower half-shell 8. It is understood that the inner face 14 and the outer face 15 of each of the half-shells 7, 8 are inscribed in two horizontal planes parallel to each other.
• Each half-shell 7.8 thus defines a concave volume or space delimited by the front face 10 and the lateral parts 13.
• the inner face 14 of the upper half-shell 7 corresponds to a lower face of this upper half-shell 7 whereas the inner face 14 of the lower half-shell 8 corresponds to one face. upper of this lower half-shell 8.
• the terms “superior” and “lower” refer to a positioning along the vertical direction V as shown in the figures.
• each half-shell 7, 8 is delimited by edges 16 which form a peripheral connecting surface between the two half-shells 7, 8. So that the figures remain readable, all the edges 16 are not referenced However, it is understood that these edges 16 form, together, a continuous and uninterrupted delimitation of the inner faces 14 of each half-shell 7, 8.
• Each inner face 14 of each half-shell 7, 8 also comprises a plurality of ribs 17 which extend from one edge 16 to another edge 16 of this inner face 14.
• the inner face 14 of the upper half-shell 7 thus comprises a plurality of first ribs 17 and the inner face 14 of the lower half-shell 8 comprises a plurality of second ribs 17.
• the first ribs 17 of the upper half-shell 7 form, with the second ribs 17 of the lower half-shell 8, an internal connecting surface between the two half-shells 7, 8. It is understood that these first ribs 17 and these second ribs 17 face each other in pairs to form this internal connecting surface, that is to say that each first rib 17 formed on the inner face 14 of the upper half-shell 7 can be secured to one second ribs 17 formed on the inner face 14 of the lower half-shell 8. More specifically, each first rib 17 of the upper half-shell 7 comprises at least one first free edge facing a first free edge of a second rib 17 of the lower half-shell 8. These free edges form the internal connecting surface of the two half-shells 7, 8.
• each half-shell 7, 8 comprises a first series of ribs 171, each of the ribs of this first series extending at least from the inside face 14 of the half-shell concerned and up to 'to the outer face 15 of this half-shell.
• the ribs 17 of this first series of ribs 171 extend parallel to the longitudinal axis L, so as to form a series along the transverse axis T.
• the ribs 17 of the first series of ribs 171 are formed at the level of the front face 10 of each half-shell 7, 8 and at the side portions 13 of these half-ribs. 7, 8.
• the ribs 17 of the first series of ribs 171 participate in the formation of the cross member and the formation of the shock absorbers, being arranged continuously from a transverse end to a other of the entire bumper.
• These ribs 17 each comprise a first edge 25 which participates in the internal connecting surface and a second edge 26 which participates in the delimitation of the front face 10 of each half-shell 7, 8.
• the first edge 25 extends longitudinally between two edges 16 defining the inner face 14 of the half-shell 7, 8 concerned and the second edge 26 extends vertically, that is to say parallel to the axis V of the trihedron worn in the figures, from the inner face 14 to the outer face 15 of said half-shell 7, 8. It is therefore understood that the first edge 25 of a rib of the first series of ribs 171 is extends perpendicularly to the second edge 26 of the same rib.
• Each half-shell 7, 8 further comprises a second series of ribs 172 arranged in series along the longitudinal axis L.
• the ribs of this second series of ribs 172 extend parallel to the transverse axis T, being provided only at the side portions 13 of the half-shells 7, 8, that is to say that this second series of ribs 172 only participate in the joining of the shock-absorbing half-shocks.
• this network 18 of ribs 17 is a matrix network formed on the one hand by the first ridges 25 of the ribs of the first series of ribs 171 and secondly by the free ends of the ribs 17 of the second series of ribs 172.
• the ribs of this second series of ribs 172 comprise a single edge extending between two edges 16 of the inner face 14 of the half-shell concerned, and along the transverse axis T. This single edge thus extends perpendicularly to the first edges 25 and the second edges 26 of the ribs of the first series of ribs 171.
• each rib of the first series of ribs 171 of the upper half-shell 7 is rendered integral with a corresponding rib of the first series of ribs 171 of the lower half-shell 8, by joining at their respective first edge 25.
• each rib 17 of the second series of ribs 172 of the upper half-shell 7 is joined in pairs with the ribs 17 of the second series of ribs 172 of the lower half-shell 8.
• each rib 17 of the second series of ribs 172 of the upper half-shell 7 is secured to a corresponding rib 17 of the second series of ribs 172 of the lower half-shell 8, by joining at their respective edges.
• the first ridges 25 of the ribs of the first series of ribs 171 and the free ends, or ridges, of the ribs of the second series of ribs 172 thus form the internal connecting surface between the two half-shells 7, 8.
• the reinforcing piece 9 is delimited by a peripheral edge 22 and comprises a front surface 27 facing the outside environment of the vehicle on which the bumper assembly is intended to be mounted and a rear surface 28 facing towards the outside.
• two half-shells 7, 8 forming the first part of the cross.
• the reinforcing piece 9 is secured to the first portion 19 of the cross member at its peripheral edge 22. It is understood that this peripheral edge 22 is secured to a peripheral edge delimiting the first portion of the cross member, as will be described hereinafter with reference to FIG.
• the reinforcement piece 9 has a transverse dimension, that is to say a dimension measured parallel to the transverse axis T, substantially equivalent to a transverse dimension of the front faces 10 of each half -coque 7, 8, that is to say a dimension measured along the transverse axis T of these front faces 10.
• the rear surface 28 of the reinforcing member 9 may have at least one rib, here not shown . This at least one rib is then formed opposite one of the ribs of the first series of ribs 171 half-shells 7, 8 to allow the attachment of the reinforcing piece 9 on the first part 19 of the cross.
• the upper half-shell 7 and the lower half-shell 8 are joined together at a peripheral connecting surface 23 shown in FIG. 3 and at an internal, non-visible connection surface.
• this internal connecting surface forming part of a horizontal plane, that is to say a plane in which the longitudinal axis L and the transverse axis T are inscribed.
• the second ridges 26 of the ribs of the first series of ribs 171 of each half-shell 7, 8 delimit a front face 20 of the first portion 19 of the cross-bar formed by the joining of the half-shells. 7, 8 between them. It is understood that the front face 20 of the first part 19 of the cross member results from the assembly of the two half-shells 7, 8 and thus comprises the respective front faces 10 of each of these half-shells 7, 8.
• the front face 20 of this first part 19 of the cross member is delimited, peripherally, by a continuous periphery 21 intended to be secured to the reinforcing piece, and more specifically to the peripheral edge of this reinforcing piece, as previously described. .
• This reinforcement piece thus forms a second portion of the cross member of the bumper assembly according to the present invention.
• This reinforcement piece is also configured to form a hollow body when it is secured to the two half-shells 7, 8, this hollow body being intended to absorb at least part of the shocks suffered by the bumper assembly by allowing a deformation of the cross.
• the reinforcing piece has a convex shape that creates a space between its rear surface and the front face 20 of the first portion 19 of the cross.
• This hollow body may extend over all or part of a transverse dimension of the cross member, this transverse dimension being measured along the transverse axis T between the ends transverse of this cross.
• this hollow body may extend transversely from one transverse end to the other or only along the central portion of the cross member.
• the crossmember of the bumper assembly 1 comprises the first part 19 resulting from the joining of the two half-shells 7, 8 between them and the second part formed by the part of reinforcement 9 ⁇ It is therefore the assembly of the two half-shells 7, 8 and 9 of this reinforcing piece which forms the cross member of the cbocs assembly 1.
• FIG. 4 is a schematic representation of a section of the first portion 19 of the cross-member made in a vertical and transverse plane, illustrated in FIG.
• the perispherical bonding surface 23 is formed between the edges 16 defining the inner faces 14 of the half-shells 7, 8 and the inner connecting surface 24 is formed between the ribs 17 formed on these half-shells 7, 8.
• this plane P is a borizontal plane, parallel to a plane transverse and longitudinal of the trihedron shown in FIG.
• the internal connecting surface 24 is made by a plurality of first ridges 25 of the ribs of the first series of ribs 171 and by a plurality of single ridges of the ribs of the second series of ribs 172, all these ribs 17 then being secured between they two by two as previously described, that is to say a rib of a half-shell with a corresponding rib of the other half-shell.
• FIG. 4 only the ribs of the first series of ribs 171 have been illustrated, to make the brazing zone of the ribs of the half-shells more visible to each other, it being understood that the ridges of the ribs of the second series ribs 172 may be brazed together in the same way.
• the joining of the ribs 17 to one another is scbatized by a single point, but it is understood that these ribs 17 can be secured along their entire longitudinal dimension.
• all the ribs of the first rib series of the two half-shells and all the ribs of the second series of ribs of these two half-shells can participate in the formation of the surface of internal link.
• only a portion of these ribs can be secured, depending on the desired level of resistance.
• the ribs of the same series of ribs then have different dimensions from each other so that only a portion of these ribs are secured to each other.
• the two half-shells 7, 8 are secured together preferably by brazing or gluing. These assembly techniques in fact make it possible to maximize the bonding surfaces and thus to distribute the forces supported by the half-shells 7, 8 in order to strengthen these bonding surfaces, which are more fragile than the rest of the bumper assembly.
• the ribs 17 also play a role of shock absorption.
• these ribs 17 not only make it possible to secure each of the parts together but also participate in the main function of the bumper assembly according to the present invention, namely to absorb shocks to limit the damage caused by these impacts on the vehicle. or on the users of this vehicle.
• the invention thus provides a bumper assembly advantageously made of a composite material, simpler to manufacture than those which currently exist and also less expensive.
• the bumper assembly according to the present invention results from the assembly of only three parts, which makes it possible to limit the junction zones between said parts and thus to reinforce the general structure of this bumper assembly since these junction areas are all points of weakness for the entire bumper.
• two of these three parts are symmetrical, which allows to design them simultaneously, thanks to a single mold, further reducing manufacturing costs and logistics issues.
• the invention can not be limited to the means and configurations described and illustrated here, and it also extends to any equivalent means or configurations and any technically operating combination of such means.
• the dimensions and shapes of the half-shells and the reinforcing piece can be modified without harming the invention, insofar as they fulfill the functionalities described in this document.

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Vibration Dampers (AREA)
• Body Structure For Vehicles (AREA)

Applications Claiming Priority (2)

Publications (1)

Family

ID=60450809

Family Applications (1)

Country Status (3)

Family Cites Families (5)

• 2017
  • 2017-09-01 FR FR1758080A patent/FR3070644B1/fr not_active Expired - Fee Related
• 2018
  • 2018-08-09 EP EP18765696.2A patent/EP3661814A1/de not_active Withdrawn
  • 2018-08-09 WO PCT/FR2018/052045 patent/WO2019043314A1/fr unknown

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